This document discusses igneous rocks and magma. It describes how igneous rocks form from the cooling and solidification of magma. Magma is the molten rock found underground or lava if at the surface. Factors like cooling rate affect the texture of the igneous rock. Composition depends on minerals present, with granitic rocks being felsic and basaltic rocks being mafic. Magma evolves as it cools via processes like differentiation, assimilation, and mixing.
2. General characteristics
of magma
• Igneous rocks form as molten rock
cools and solidifies
• General characteristics of magma:
• Parent material of igneous rocks
• Forms from partial melting of rocks
• Magma at surface is called lava
3. General characteristics
of magma
• General characteristic of magma
• Rocks formed from lava = extrusive, or
volcanic rocks
• Rocks formed from magma at depth =
intrusive, or plutonic rocks
4. General characteristics
of magma
• The nature of magma
• Consists of three components:
– Liquid portion = melt
– Solids, if any, are silicate minerals
– Volatiles = dissolved gases in the melt,
including water vapor (H2O), carbon dioxide
(CO2), and sulfur dioxide (SO2)
5. General characteristics
of magma
• Crystallization of magma
• Cooling of magma results in the
systematic arrangement of ions into
orderly patterns
• The silicate minerals resulting from
crystallization form in a predictable
order
• Texture - size and arrangement of
mineral grains
6. Igneous textures
• Texture is used to describe the
overall appearance of a rock based
on the size, shape, and arrangement
of interlocking minerals
• Factors affecting crystal size
• Rate of cooling
– Slow rate = fewer but larger crystals
– Fast rate = many small crystals
– Very fast rate forms glass
11. Igneous textures
• Types of igneous textures
• Porphyritic texture
– Minerals form at different temperatures
– Large crystals (phenocrysts) are embedded
in a matrix of smaller crystals (groundmass)
• Glassy texture
– Very rapid cooling of lava
– Resulting rock is called obsidian
12. Igneous textures
• Types of igneous textures
• Pyroclastic texture
– Fragmental appearance produced by violent
volcanic eruptions
– Often appear more similar to sedimentary
rocks
• Pegmatitic texture
– Exceptionally coarse grained
– Form in late stages of crystallization of
granitic magmas
15. Igneous compositions
• Igneous rocks are composed primarily
of silicate minerals
• Dark (or ferromagnesian) silicates
– Olivine, pyroxene, amphibole, and biotite
mica
• Light (or nonferromagnesian) silicates
– Quartz, muscovite mica, and feldspars
16.
17. Igneous compositions
• Granitic versus basaltic compositions
• Granitic composition
– Light-colored silicates
– Termed felsic (feldspar and silica) in
composition
– High amounts of silica (SiO2)
– Major constituent of continental crust
18. Igneous compositions
• Granitic versus basaltic compositions
• Basaltic composition
– Dark silicates and calcium-rich feldspar
– Termed mafic (magnesium and ferrum, for
iron) in composition
– Higher dense than granitic rocks
– Comprise the ocean floor and many
volcanic islands
19. Basaltic lava dropping into the ocean along Kilauea Volcano along
the southeastern coast of the big island of Hawaii
20. Igneous compositions
• Other compositional groups
• Intermediate (or andesitic) composition
– Contain 25% or more dark silicate minerals
– Associated with explosive volcanic activity
• Ultramafic composition
– Rare composition that is high in magnesium
and iron
– Composed entirely of ferromagnesian
silicates
21. Igneous compositions
• Silica content as an indicator of
composition
• Exhibits a considerable range in the
crust
– 45% to 70%
• Silica content influences magma
behavior
• Granitic magmas = high silica content
and viscous
• Basaltic magmas = much lower silica
content and more fluid-like behavior
22.
23. Igneous compositions
• Naming igneous rocks – granitic rocks
• Granite
– Phaneritic
– Over 25% quartz, about 65% or more
feldspar
– Very abundant - often associated with
mountain building
– The term granite includes a wide range of
mineral compositions
25. Igneous compositions
• Naming igneous rocks – granitic rocks
• Rhyolite
– Extrusive equivalent of granite
– May contain glass fragments and vesicles
– Aphanitic texture
– Less common and less voluminous than
granite
36. Igneous compositions
• Naming igneous rocks – pyroclastic
rocks
• Composed of fragments ejected during
a volcanic eruption
• Varieties
– Tuff = ash-sized fragments
– Volcanic breccia = particles larger than ash
37.
38. Origin of magma
• Highly debated topic
• Generating magma from solid rock
• Role of heat
– Temperature increases in the upper crust
(geothermal gradient) average between 20oC
to 30oC per kilometer of depth
– Rocks in the lower crust and upper mantle
are near their melting points
– Any additional heat may induce melting
39. Origin of magma
• Role of pressure
– Increases in confining pressure cause an
increase in a rock’s melting temperature
– When confining pressures drop,
decompression melting occurs
• Role of volatiles
– Volatiles (primarily water) cause rocks to
melt at lower temperatures
– Important factor where oceanic lithosphere
descends into the mantle
41. Evolution of magmas
• A single volcano may extrude lavas exhibiting
very different compositions
• Each volcanic eruption tends to exhibit a
unique geochemical fingerprint, defined by
trace element percentages
• Bowen’s reaction series
• Minerals crystallize in a systematic fashion
based on their melting points
• During crystallization, the composition of the
liquid portion of the magma continually changes
43. Evolution of magmas
• Processes responsible for changing a
magma’s composition
• Magmatic differentiation
– Separation of a melt from earlier formed
crystals
• Assimilation
– Changing a magma’s composition by the
incorporation of surrounding rock bodies
into a magma
44. Magma evolves as the
hotter minerals crystallize
and settle to the bottom of
the magma chamber
45. Evolution of magmas
• Processes responsible for changing a
magma’s composition
• Magma mixing
– Two chemically distinct magmas may
produce a composition quite different from
either original magma
47. Evolution of magmas
• Partial melting and magma formation
• Incomplete melting of rocks is known as
partial melting
• Formation of basaltic magmas
– Most originate from partial melting of
ultramafic rock in the mantle at oceanic
ridges
– Large outpourings of basaltic magma are
common at Earth’s surface
48. Evolution of magmas
• Partial melting and magma formation
• Formation of andesitic magmas
– Produced by interaction of basaltic magmas
and more silica-rich rocks in the crust
– May also evolve by magmatic differentiation
49. Evolution of magmas
• Partial melting and magma formation
• Formation of granitic magmas
– Most likely form as the end product of
crystallization of andesitic magma
– Granitic magmas are more viscous than
other magmas so they tend to lose their
mobility before reaching the surface
– Tend to produce large plutonic structures